Murray Cod Modelling to Address Key Management Actions Final Report for Project md745

The first Murray cod modelling workshop identified 3 general management areas that a management model should address:

1. Fishery management

2. Habitat and flow management

3. Trophic interaction management (Appendix 3)

A wide range of parameters have been included in the model to allow for the greatest site specific application. The parameters in the model are listed below and will be afforded greater explanation for their use in a user manual which will now be produced to accompany the model software.

Specific issues discussed relating to fishery management included changes that may occur with:

• changing the minimum legal length;

• changing/setting the maximum legal length;

• changing the bag or possession limits;

• a range of fishing effort/rate;

• adjusting the closed seasons;

• reducing illegal take;

• outlawing set lines;

• having ‘no take’ areas.

• Fishing/no fishing

• Regulations

• Minimum size

• Maximum size

• Change regulations during simulation

• Change regulations

• New minimum size

• New maximum size

• Year to change fishing

• Break between implementing new regulations

• Time step to collect statistics from

• Take rate

• Rates for legal fish to 1m

• Rates for 1m+

• Catch and release mortality rate

• Illegal fishing (Yes/No)

• Rate below minimum size

• Rate above maximum size

• Catch and release mortalities

• Stocking/no stocking

• Fingerlings

• 1 year olds

• Number of fish to be released annually

• Stocking duration

Angling regulations (bag and size limits) are key fishery management options for Murray cod. Angling regulations for Murray cod, however, vary for each State and Territory across the species’ range (Table 5) and changes to the fishing minimum and maximum legal size lengths are all allowed within the model. Fishing rates determine the take and hence contribute to overall population mortality. Fishing take rates of >15% per year have been estimated for the Murray River below Yarrawonga (Nicol et al. 2005) and the Mullaroo Creek (Saddlier et al. 2007). Further analysis indicates that for certain size classes, rates may be as high as 35% (Todd unpubl. data).

Consequently, a range of plausible take rates of 0–30% are included. An option of no take is included as a base for the model and also represents the option for a reserve or no take zone. Additional impacts on adult fish can come from illegal fishing (above bag limit, take of undersize fish and take by illegal methods) and from post –release mortalities from catch and release fish. Anglers frequently catch, and then release Murray cod either because the fish is under the legal size limit or they do not wish to keep the fish. Often the estimate of fishing effort only includes the number of fish harvested and the voluntary release of fish is ignored (Clark 1983). Hooking mortality for the released fish, however, may be considerable (Clark 1983; Muoneke and Childress 1994; Bettoli and Osborne 1998) and needs to be considered in the overall mortality estimates for the population. Stocking of hatchery produced fish is another management option that is widely used to establish or enhance stocks for angling (Harris 2005), but the success of which has rarely been assessed.

* to be increased to 60 cm after 1.12.2008.

Specific issues discussed relating to habitat and flow management included the changes that may occur to a population with:

• an increase or decrease in habitat;

• an improvement to riparian vegetation;

• reducing the impacts of cold water pollution;

• providing environmental flows at differing times, durations, etc;

• fish ways being installed along the Murray River; and

• the establishment of Habitat Management Areas.

• Habitat change selection

• Decrease/increase

• Enter the proportional change as a percentage

• Enter a time step to implement changes

While the importance of habitat to fish populations is well recognised, the impact of a habitat change on a fish population is often difficult to predict. Modelling direct impacts of habitat changes on Murray cod populations is uncertain due to a lack of knowledge of the direct relationships between habitats and population numbers and density. Such habitat changes can occur through removal or addition, impoundment of waters by weirs or reductions in flows, including the effects of drought or climate change. Modelling such scenarios was included by estimating potential changes in population carrying capacity. The change in carrying capacity was assumed to be either detrimental or beneficial equally to all life stages. It was presumed that a proportional decrease in overall habitat may result in a similar proportional decrease in population although there is usually little definitive data to prove such a change. Changes to habitat quality through changes to a particular habitat parameter (eg. wood, water velocity, depth, water quality) are even more difficult to quantify. If no quantitative measurements of habitat change can be measured (eg. an area reduction), changes may be considered in a less quantitative way using our knowledge of the species to inform the direction and proportion of the change. Projected flow data for the future years may be useful for examining the impacts of predicted climate change.

Specific issues discussed relating to habitat and flow management included the changes that may occur to a population with:

• Percentage loss

• Year fish kill begins

• Period of increased probability of fish kill

• Probability of fish kill

Impacts to early life stages

• Thermal pollution

• Thermal effects yes/no/spawning failure

• Degree of impact

• Larval mortality due to weirs (undershot or overshot, etc)

• Larval loss into irrigation off-takes

• Average adult population size

• Initial adult population size

• Density dependence

• Beverton-Holt shape

A number of significant fish kills have occurred in recent years that have impacted important Murray cod populations (Koehn 2005b; Sinclair 2005a; Lugg 2000). Such kills have effected populations to varying degrees (Koehn 2005b) and can be modelled as instantaneous percentage reduction in overall population. A range of other threats that can increase the likelihood of mortality for Murray cod have been identified (Koehn 2005; National Murray cod Recovery team 2007) and have the potential to operate at particular sites. These threats have been included as it is important to recognise that when these threats operate concurrently, their cumulative effects can pose significant impacts on populations. The impacts of changed thermal regimes downstream of dams have already been explored in other studies, effecting spawning, egg and larval survival and growth rates (Todd et al. 2005; Sherman et al. 2007). Two additional impacts on larvae may occur during the period when they are drifting in the river channel (peak of November: Koehn and Harrington 2006). The passage of larvae over weirs can be cause considerable larval mortalities (Baumgartner et al. 2006). Passage through undershot weirs can result in deaths of 52 ± 13 % of Murray cod larvae, while passage over overshot weirs can result in mortalities of 11 ± 5 % (Baumgartner et al. 2006). Larvae can also be lost from the main river channel in irrigation waters that may be extracted. While quantification of these losses has not been undertaken, it is considered that they may be considerable (Koehn et al. 2004b; King and O’Connor 2007). The ability for these threats and other management options to operate together allows cumulative impacts to be explored.

The survival and fecundity rates are specified such that, in the absence of threatening processes, the growth rate is greater than 1, i.e.  =1.2. This implies that populations will continue to grow without constraint. In section 3.5, density-dependence was discussed with the application of a Beverton-Holt function to larval development and a top down density dependent factor proportionally reducing age specific survival rates. Specifying the Beverton-Holt shape parameter determines the strength of density-dependence applied to larvae. Specifying the average adult population size sets the level above which the density dependence mechanisms exert the strongest negative feedback. A low average population size models a small population and a large value models a larger population. The initial value allows the option of beginning the population at a size other than the average population size.

Sensitivity analysis is an important part of the decision making process. Ferson and Ginzburg (1996) introduced a taxonomy of uncertainty for use when dealing with models of stochastic processes. Their system included four kinds of uncertainty:

• Structural uncertainty;

• Parameter uncertainty;

• Dependency uncertainty; and

• Shape uncertainty (about a distribution).

These four kinds of uncertainty can be characterised in two ways. They can either be instances of epistemic uncertainty resulting from incomplete information about the system in question (ignorance) or the underlying or inherent stochasticity in the system (variability) (Ferson and Ginzburg, 1996). For example, structural uncertainty may be what type of density-dependence should be used to model recruitment: a question of ignorance; or parameter uncertainty may arise from how much recruitment varies from year to year. Ferson and Ginzburg’s (1996) approach was motivated by model-building for ecological risk assessment, and it effectively summarises the kinds of things that models (and modellers) need to consider when formulating responses to environmental problems and management questions. As a rule of thumb, the four kinds of uncertainty provide the example set over which sensitivity analyses should be undertaken. The sensitivity analysis options (including changes to density dependence) allow for the exploration of parameter, dependency and shape uncertainty. In practice, undertaking sensitivity analysis requires a methodological approach to making parameter changes, then recording the metric about which the sensitivity was assessed. For example, one management metric may be the number of fish older than 20 years of age (representing most fish over 1 metre). The metric should be linked to the decision making process, that is, that metric can be used in the examination of a variety of different management actions. If undertaking sensitivity analysis leads to conflicting interpretations about which action is more effective, then it becomes important to understand what has contributed to this sensitivity. There are three metrics that are being used to determine sensitivity to management actions and they are 20 yr olds (plus), fish in the size class 60-90cm, and total adults in terms of the average minimum population size; the absolute difference in the average minimum population size and the percentage change in average minimum population size.

5.6 Some scenario examples

The following are some examples of how to use and interpret some of the output generated by the Murray cod stochastic population model. Each model ran 1 000 iterations of 50 time steps, using an average carrying capacity of 20 000 adult Murray cod and an initial population size of 20 000 fish so that the unimpacted scenario was well away from a zero population size or extinction.

5.6.1 Modelled Current Victorian regulations

The current Victorian regulations allow for fish to be kept if they are 50 cm in length or longer. There are no protections for fish over 1 metre (100 cm) other than to limit the number of fish over 75 cm that one angler may have. The take rate has been measured to be up to 30% in some reaches of the Murray River (Todd unpubl. data). The minimum population size (MPS) risk curves in Fig. 13, represent the probability that the population will fall to or below a given threshold population size at least once over the 50 times steps. The green line represents the MPS risk curve associated with no fishing (Fig. 13). Introducing a take rate of 10% increases the risks by shifting the risk curve to the left, represented by the blue line (Fig. 14). A take rate of 20% adds more risk as can be seen with the red line shifted even further to the left (Fig. 13).

5.6.2 Modelled Slot size regulations of 60–100cm

It has been proposed by some states to introduce a ‘slot-size’, where fish can only be legally taken when between certain upper and lower size limits. The risk curves in Fig. 14 are associated with the original curves found in Fig. 13, and additionally a ‘slot-size’ scenario has also been modelled where fish under 60 cm and over 100 cm are protected. The blue dashed line is the risk curve associated with a 10% take and ‘slot-size’ scenario and the red dashed line is the risk curve associated with a 20% take and ‘slot-size’ scenario. Both these scenarios reduce risk by moving the risk curve to the right.



Figure 14: Minimum population size risk curves for a modelled Murray cod population with an average carrying capacity of 20 000 adults, where the green line is the no fishing risk curve; the blue line is the risk curve for the former regulations with a take rate of 10%; and the red line is the risk curve for the former regulations with a take rate of 20%. Dashed lines are the corresponding risk curves associated with increasing the minimum size to 60 cm and protecting all fish over 100 cm.

5.6.3 Cumulative threats – multiple modelled impacts

Threatening processes do not generally happen in isolation and act cumulatively on population processes. In Fig. 15, the scenarios are:

1. the long-dashed blue line is the risk curve associated with a 10% take and ‘slot-size’ 60–100cm scenario as in Fig. 14;

2. the orange line is the risk curve associated with a 10% take and ‘slot-size’ and 15% mortality due to catch and release;

3. the brown line is the risk curve associated with a 10% take and ‘slot-size’ and 15% mortality due to catch and release and 20% larval loss associated with an overshot weir;

4. the mauve line is the risk curve associated with a 10% take and ‘slot-size’ and 15% mortality due to catch and release and 20% larval loss associated with an overshot weir and 20% larval loss due to irrigation off take;

5. the olive line is the risk curve associated with a 10% take and ‘slot-size’ and 15% mortality due to catch and release and 20% larval loss associated with an overshot weir and 20% larval loss due to irrigation off take and a 20% reduction in the carrying capacity; and

6. the yellow line is the risk curve associated with a 20% take and ‘slot-size’ and 15% mortality due to catch and release and 20% larval loss associated with an overshot weir and 20% larval loss due to irrigation off take and a 20% reduction in the carrying capacity.



Figure 15: Minimum population size risk curves for a modelled Murray cod population for scenarios 1–6: 
1) dashed blue line; 2) orange line; 3) brown line; 4) mauve line; 5) olive line; and 6) yellow line.

As threatening processes are included in the model they shift the risk curve further to the left, where some have a greater impact than others. A method for quantifying the cumulative threatening processes is to calculate the average minimum population size for each of the risk curves (Table 6). The average minimum population size can be used to quantify the differences between risk curves. For example a population facing the single threat associated with scenario 1 is expected to have approximately 3075 more fish than the same population with multiple threats as in scenario 5, (8289.43 - 5214.52 = 3074.91).

Given the number of parameters included in the model, the number of different management scenarios that can be considered, and the different characteristics of each management site, there are a multitude of scenario combinations that can be explored. It is not the intention of this report to provide a large number of such examples, especially as they could be misinterpreted as ‘answers’ to particular management issues. The scenarios given above provide examples of how management options may be assessed using the model and it is important that each management decision is worked through the model on a site by site basis to ensure that all threats are considered.

The modeling of all scenarios was undertaken using the software package ESSENTIAL (Todd and Lovelace 2009). ESSENTIAL is a highly flexible stochastic modelling platform that allows both expert model development as well as general use by way of access to a limited suite of parameters. Data can be accessed on all parameters over all time steps and iterations. A specific application of ESSENTIAL is being developed to provide the Murray—Darling Basin Commission with a stand alone Murray cod Management Model.

The management scenarios modelled were established through a highly consultative workshop approach and included various options for changes in angling regulations in relation to size and bag limits and the potential impacts of changes to habitats. A no take scenario which equates to a fishery closure was used as the base model. Modelled management scenarios for Murray cod indicate that the risk to populations can be reduced substantially by the appropriate changes to management actions. In particular, changes to the size limits on angler take can have a major impact on population persistence. The implementation of a slot size that protects both smaller and larger fish reduced population risk considerably. Our results support recent changes toward introduction of a legal take slot size of 60–100 cm by some States. Whilst habitat changes are difficult to quantify, it was illustrated that reductions in carrying capacity can place additional risk on populations, particularly when combined with angler take. Importantly, the cumulative impacts of less recognised threats such as thermal pollution, fish kills and mortalities to larvae over weirs and losses into irrigation off-takes can be explored and need to be recognised as having the potential to contribute significantly to mortalities at certain sites.

The cumulative impacts of multiple threats on fish populations are rarely considered. Their potential cumulative or compounding affects, however can be greater than some of the more recognised impacts such as angler take. While some impacts, such as cold water releases have been explored for Murray cod (Todd et al. 2005; Sherman et al. 2007), many others have not been considered. Not all of these impacts have a linear response and some such as thermal impacts may over-ride all others. For example, if water temperatures do not reach the recognised spawning temperature of 15ºC (Humphries 2005; Koehn and Harrington 2006), then spawning and hence recruitment may not occur. Impacts on larvae, such as temperature, damage passing through weirs, and diversions into irrigation channels, only occur through the period when larvae are drifting (peak in November in the Murray River: Koehn and Harrington 2006). They can, however, have major impacts on long-term population viability. Such impacts are not constant and may be quite site specific. The inclusion of the ability to test such cumulative impacts in the model are useful to illustrate how protection at these vulnerable and less obvious life stages, from less well-recognised threats, can still have major effects on the species’ conservation and the number of fish available to anglers.

There is an increasing trend for catch-and-release fishing, including for Murray cod. While this may initially reduce overall take, it may still contribute significantly to overall mortality. In a review of catch and release studies in North America, Bartholomew and Bohnsack (2005) reported an average catch and release mortality of 18%, although this varied greatly by species and within species. Significant mortality factors include: anatomical hooking location; use of natural bait; hook removal; hook type (J or circle, barbed, barbless); deeper depth of capture; warmer water temperatures; and extended playing and handling times. While mortality distributions varied between species in that study, they were, however, similar for salmonids, marine and freshwater species. Results from that work also suggested that many of the reported mortality rates were underestimates of actual mortality (especially for marine species) as they rarely included predation during capture or after release. While this factor may be less relevant to large Murray cod it may have a greater impact on undersize fish. There is also a lack of data concerning any cumulative effect of multiple hookings. Hence, the reporting of removal rates may not reflect the total mortality or impacts of fishing because they do not reflect mortality for the released fish and this needs to be considered in overall mortality estimates for the population (Bartholomew and Bohnsack 2005).

While there is considerable anecdotal information about illegal removal of Murray cod in certain areas, there is little quantification of the amount of illegal removal and what impact this may have on the population (Joy Sloan, Victorian Fisheries, pers. comm.). Such illegal removal can be in the form of fish which do not comply with legal size or bag limits or those which may be taken by illegal methods such as nets or set-lines. It has been recognised that removal of undersized Murray cod, especially 45–50 cm fish, does occur (Nicol et al. 2005). Removal of fish, either by legal or illegal means, impacts on a population’s resilience and increases the risk of population decline. While sometimes difficult to quantify, all removal of fish must be taken into account in the management of Murray cod populations and, consequently, any action that reduces the illegal removal of fish will reduce the risk to the population.

Management of recreational angling for Murray cod is not uniform across jurisdictions. South Australia has recently implemented a minimum legal size of 60 cm and a maximum size of 100 cm (slot size 60-100 cm). Modelling results from this study would support the introduction of this slot size limit as it reduces population risk (Figure 15). While recent changes to New South Wales regulations also include this slot size, it still allows the take of one fish above 75 cm. This does not ensure compliance with the scenario modelled in this study and will have additional risk. Site specific increase in take can also occur if angling becomes more restricted in a nearby area. The recent changes to both South Australia and New South Wales regulations may transfer some angling pressure to Victorian waters in border areas. To avoid this there is a need for uniformity in regulations to be achieved as quickly as possible. Such issues could be avoided through a more uniform multi-state approach to Murray cod management.

The recognition of the cumulative impacts of co-occurring threats is important when assessing risk to populations. There are several threats to Murray cod which are not well recognised (Koehn 2005b) and to date have received relatively little recognition in population management (eg. larval loss in irrigation off-takes). When operating with other threats, however, they increase the risk of a low population size. The example provided in section 5.6.3 highlights their cumulative impacts, and Table 6 indicates how the results from the model may be used to compare these impacts. Importantly, the inclusion of the relevant parameters in the model allows these threats to be assessed on a site by site basis.

At first glance, it could be perceived that the management of the recreational fishery for Murray cod and the species’ conservation may be in conflict. However, assessment of this through the recovery planning process, which involved managers, scientists and stakeholders from both conservation and recreational fishery sectors indicated that there was general commonality between objectives (National Murray Cod Recovery Team 2007). Moreover, the methods used for fishery and conservation planning contain essentially similar elements and could be formally incorporated into a more comprehensive approach to the management of Murray cod. Fisheries and conservation management are both characterised by conflicting objectives, multiple stakeholders with divergent interests and high levels of uncertainty about the dynamics of the resources (Smith et al. 1999; Pressey et al. 2007). Predicting the results of any management action is uncertain because the dynamics of the ecosystems and their processes are complex and poorly understood, with limited understanding of individual threats, combinations of threats, new threats and the dynamic nature of threats, ecosystem and anthropogenic changes (Sainsbury et al. 2000; Pressey et al. 2007).

Management-Strategy-Evaluations (MSE) is a process used in commercial fisheries to assess the consequences of a range of management options and trade-offs (Smith et al. 1999). It develops a clearly defined set of management objectives, a set of performance criteria, a set of management strategies or options and a means of calculating the performance criteria for each objective. Objectives rely on simulation testing of the whole management process using performance measures derived from operational objectives (Sainsbury et al. 2000). MSE deals explicitly with uncertainty and seeks to identify trade-offs among management objectives and evaluate the consequences of alternative strategies or decisions, rather than trying to seek ‘optimal’ solutions. It seeks to provide decision makers with information on which to base management choices and usually involves methods such as modelling to test management scenarios (Smith et al. 1999). MSE incorporates many of the concepts and techniques of adaptive management (AM) that have been developed as a framework for addressing the general problems of management under uncertainty (Walters 1986; Walters and Hilborn 1978; Smith and Walters 1981). AM and Adaptive Environmental Assessment and Management (Holling 1978) brings to management the philosophy of scientific method where management actions are implemented in a well-defined framework for goal-setting, monitoring and evaluation of outcomes (Walters 1986; Clark et al., 1995). It aims to deal explicitly with uncertainty through a process of identification and analysis of critical aspects of management (Walters and Hilborn 1978; Bearlin et al. 2002).

Models play an important role in AM and MSE processes and aid the development of cooperative and quantitative approaches to management (Starfield 1997). Modelling within such processes allow simulation of: the observation or monitoring process; scientific assessment or data analysis; how the results of the data analysis will be used for management purposes and the implementation of management decisions (Sainsbury et al. 2000). In applying a precautionary approach, such as may be needed for threatened species, this allows different levels of precaution to be examined (Sainsbury et al. 2000). Management under uncertainty necessitates the importance of feedback between the rate of exploitation and learning about the stock dynamics (Smith 1993). Uncertainty in these processes can occur through: model error (eg. inappropriate function choice), process noise (eg. recruitment variability), data error (eg. ageing), bias in estimators, lack of contrast in data, or failure to achieve the managed target (Smith 1994; Bearlin et al. 2002). Scientific input into stock assessment and MSE remains a key requirement for an effective management system (Smith et al. 1999; Prager and Rosenberg 2008). Difficulties in stock-recruitment relationships and optimal policies can be due to parameter uncertainty and well as environmental variation. Much of our understanding of commercial fish stocks dynamics has come from information generated by the process of harvesting those stocks (Smith and Walters 1981). Such collection obviously does not occur for threatened species and there is a need for collection of data comparable to that which would normally be collected as harvest for commercial fisheries. In the case of Murray cod, some data may be obtained from recreational anglers. The collection of these data needs to be undertaken in a scientific manner, designed to answer management questions, possibly supplemented by scientific data collection. The involvement in monitoring and data collection by this important stakeholder group importantly helps to ensure ‘ownership’ of any stock/conservation assessment and subsequent management decisions.

There are a series of data gaps that have been identified in the process of this study that, if filled through appropriate monitoring and data collection, would reduce the uncertainty of the model and its outputs. The size of the resource and absolute catch/take rates are unknown, particularly on a regional or site basis. Catch and release mortality rates for different size classes and the cumulative effect of multiple captures need quantification. Data on age-size, size distributions and size-maturity relationships inform important parameters in the model. Not all of these relationships are well understood although it would be relatively simple to improve our understanding of these relationships. For example, fish carcases were not retained from fish kills and, as a consequence, an opportunity to gain valuable scientific data on the age-structure of the Murray cod populations was lost (Koehn 2005b). Such data could have been used to inform the model and to plan restorative actions. Similarly, such data could also be collected from the carcases of fish that are kept by anglers. This needs to be undertaken in a scientific manner on a regional basis. The recent change in angling regulations provides an opportunity to test predicted outcomes through appropriate monitoring.

Murray cod is a threatened species which needs immediate management actions in order to rehabilitate populations. Like many other fish species it is subject to habitat changes and other threats, and, as a popular angling species, it is subject to take. All of these impacts may increase the risk of population reductions or extinction and need to be monitored regularly so that appropriate changes to management actions can be quickly adapted if needed. The methodology presented here offers a formalised, rational, modelling approach which can form the basis for the assessment and prioritisation of management options for Murray cod to minimise the risk to populations. Such modelling also highlights data gaps and monitoring requirements and can become an integral part of the conservation and fishery management process and provides a tool for exploring the outcomes of management scenarios at both the regional and local scale. The modelling process has helped facilitate interagency Murray cod management and emphasises the need for coordination between fishery managers, water and environmental protection/conservation agencies (Southwick and Loftus 2003). Deliberate, active adaptive policy appears crucial in managing stock-recruitment systems (Smith and Walters 1981) not only to commercial species but also to threatened species recovery (Bearlin et al. 2002). It involves a range of stakeholders including: scientists, industry and conservation NGO’s (Smith et al. 2001). These relationships have been facilitated for Murray cod through the formation of the Recovery Team and the Murray cod Taskforce (Lintermans and Phillips 2005) and this modelling process. Management needs to be further formalised with consideration given to formal review of progress (Prager and Rosenberg 2008). The outputs from modelling these scenarios, together with additional data collection and inputs (eg. creel surveys) will provide a solid basis for improved management of Murray cod population which can ensure its sustainability. Changes in angling regulations provide an opportunity to test predicted outcomes through appropriate monitoring.